Semiconductor devices and corresponding methods of manufacture are disclosed. The devices may include a first epitaxial structure disposed below a dielectric pillar, a second epitaxial structure disposed above the first epitaxial structure and around the dielectric pillar, a third epitaxial structure disposed above the second epitaxial structure and around the dielectric pillar, and a fourth epitaxial structure disposed above the third epitaxial structure and around the dielectric pillar. The second and third epitaxial structures may each have a portion inwardly extending toward a central axis of the dielectric pillar.

A method of forming an isolation trench, can include: forming a trench in a substrate, the trench extending from a first surface of the substrate to an interior of the substrate; and forming at least two layers of different filling materials in the trench to completely fill the trench, where a step coverage of each layer of filling material is better than a step coverage of the previous layer of filling material.

A Schottky barrier diode includes a semiconductor layer having a plurality of trenches formed by digging in from a top surface and having mesa portions formed between adjacent trenches, and a Schottky metal formed to contact the top surface of the semiconductor layer including inner surfaces of the trenches.

A first impurity diffusion region is provided within a semiconductor substrate, a second impurity diffusion region is provided within the first impurity diffusion region, a third impurity diffusion region is provided within the second impurity diffusion region, a first portion of a fourth impurity diffusion region is provided within the second impurity diffusion region so as to be spaced from the third impurity diffusion region, and a second portion of the fourth impurity diffusion region is provided in a third portion of the first impurity diffusion region on a side of a surface of the semiconductor substrate, a first contact is provided so as to be in contact with the second portion, the first contact and the third portion overlap in plan view, and a first power supply is connected to the third impurity diffusion region.

Graphite-based devices with a reduced characteristic dimension and methods for forming such devices are provided. One or more thin films are deposited onto a substrate and undesired portions of the deposited thin film or thin films are removed to produce processed elements with reduced characteristic dimensions. Graphene layers are generated on selected processed elements or exposed portions of the substrate after removal of the processed elements. Multiple sets of graphene layers can be generated, each with a different physical characteristic, thereby producing a graphite-based device with multiple functionalities in the same device.

Diodes and fabrication methods thereof are presented. The diodes include, for instance: a first semiconductor region disposed at least partially within a substrate, the first semiconductor region having a first conductivity type; and a second semiconductor region disposed at least partially within the first semiconductor region, the second semiconductor region having a second conductivity type, wherein the first semiconductor region separates the second semiconductor region from the substrate. In one embodiment, the substrate and the first semiconductor region have U-shaped boundary. In a further embodiment, the first semiconductor region comprises an alloy of a first material and a second material, where the concentration of the second material varies from a maximum to a minimum, where the first semiconductor region adjacent to the second semiconductor region has the minimum of the concentration of the second material.

One aspect of this disclosure is a power amplifier module that includes a power amplifier configured to provide a radio frequency signal at an output, an output matching network coupled to the output of the power amplifier and configured to provide impedance matching at a fundamental frequency of the radio frequency signal, and a harmonic termination circuit coupled to the output of the power amplifier. The power amplifier is included on a power amplifier die. The output matching network can include a first circuit element electrically connected to an output of the power amplifier by way of a pad on a top surface of a conductive trace, in which the top surface has an unplated portion between the pad the power amplifier die. The harmonic termination circuit can include a second circuit element. The first and second circuit elements can have separate electrical connections to the power amplifier die. Other embodiments of the module are provided along with related methods and components thereof.

A semiconductor device includes one nanowire structure disposed on semiconductor substrate and extending in first direction on semiconductor substrate. Each nanowire structure includes plurality of nanowires extending along first direction and arranged in second direction, the second direction being substantially perpendicular to first direction. Each nanowire is spaced-apart from immediately adjacent nanowire. A gate structure extends in third direction over first region of nanowire structure, the third direction being substantially perpendicular to both first direction and second direction. The gate structure includes a gate electrode. Source/drain regions are disposed over second region of nanowire structure, the second region being located on opposing sides of gate structure. The gate electrode wraps around each nanowire. When viewed in cross section taken along third direction, each nanowire in nanowire structure is differently shaped from other nanowires, and each nanowire has substantially same cross-sectional area as other nanowires in nanowire structure.

A semiconductor device includes a setting circuit and a reset circuit. The setting circuit includes a latch circuit having first and second inverters driven by a first power voltage whose level is fixed and a first transistor which is switched between an ON state and an OFF state on the basis of a level of a second power voltage whose level varies depending on a surrounding environment, and sets data corresponding to a reference voltage to the latch circuit in response to the first transistor being switched to the ON state. The reset circuit includes an N-type second transistor connected to an output of the first inverter and an input of the second inverter. The second transistor sets data corresponding to the reference voltage to the latch circuit in response to the second voltage being equal to or lower than a predetermined voltage value.

Wafers, chips, or dies that contain fill cells with structures configured to obtain in-line data via non-contact electrical measurements (NCEM). Such NCEM-enabled fill cells may target/expose a variety of open-circuit, short-circuit, leakage, or excessive resistance failure modes, including GATE-snake-open and/or GATE-snake-resistance failure modes. Such wafers, chips, or dies may include Designs of Experiments (DOEs), comprised of multiple NCEM-enabled fill cells, in at least two variants, all targeted to the same failure mode.